System and Method for Extended Peripheral Component Interconnect Express Fabrics

1. An extended peripheral component interconnect express (PCIe) topology comprising: a host PCIe fabric comprising a host root complex, the host PCIe fabric having a first set of bus numbers and a first memory mapped input/output (MMIO) space on a host central processing unit (CPU); and an extended PCIe fabric comprising a root complex endpoint (RCEP) as part of an endpoint of the host PCIe fabric, the extended PCIe fabric having a second set of bus numbers and a second MMIO space separate from the first set of bus numbers and the first MMIO space, respectively, wherein the second MMIO space of the extended PCIe fabric is mapped to a physical address space on the host CPU, wherein the host PCIe fabric is a bridge between the extended PCIe fabric and the host CPU, and wherein the second set of bus numbers allows additional devices to be connected to the host CPU beyond a capacity of the host PCIe fabric as provided by resources of the host root complex.

2. The PCIe topology of claim 1 , wherein the RCEP is a bridge between an endpoint of the extended PCIe fabric and the host PCIe fabric.

3. The PCIe topology of claim 1 , wherein the physical address space is the first MMIO space.

4. The PCIe topology of claim 3 , wherein a 32-bit memory space of the extended fabric is mapped to a 64-bit MMIO space of the first MMIO space.

5. The PCIe topology of claim 3 , wherein a 64-bit memory space of the extended fabric is mapped to a 64-bit MMIO space of the first MMIO space.

6. The PCIe topology of claim 1 , wherein a PCIe configuration space of the extended PCIe fabric is mapped to a 64-bit MMIO space of the first MMIO space.

7. The PCIe topology of claim 6 , wherein each device function of the extended PCIe fabric is mapped to a respective four kilobytes of the 64-bit MMIO space.

8. The PCIe topology of claim 6 , wherein configuration registers for each device function associated with the extended PCIe fabric are configured to be addressed using base/device/function addressing.

9. The PCIe topology of claim 1 , wherein the second set of bus numbers includes up to 256 unique bus numbers for the extended PCIe fabric.

10. The PCIe topology of claim 1 , wherein the RCEP is configured to isolate faults originating on the extended PCIe fabric.

11. The PCIe topology of claim 1 , wherein the extended PCIe fabric interacts with a peripheral device in a same manner as the host PCIe fabric.

12. The PCIe topology of claim 1 , wherein the host CPU manages the first set of bus numbers, the second set of bus numbers, the first MMIO space, and the second MMIO space.

13. A peripheral component interconnect express (PCIe) topology comprising an extended PCIe fabric, wherein the extended PCIe fabric comprises a root complex end point (RCEP) device, wherein the RCEP device is configured to be part of an endpoint of a first-level PCIe fabric, and wherein the extended PCIe fabric comprises: a first memory mapped input/output (MMIO) space mapped to an address space on a host central processing unit (CPU), wherein the first-level PCIe fabric comprises a second MMIO space on the host CPU, and wherein the first-level PCIe fabric is a bridge between the extended PCIe fabric and the host CPU; and a set of bus numbers, and wherein the set of bus numbers allows additional devices to be connected to the host CPU beyond a capacity of the first-level PCIe fabric as provided by resources of a first-level root complex of the first-level PCIe fabric.

14. The PCIe topology of claim 13 , wherein the MMIO space is mapped to a 64-bit addressable physical address space of the second MMIO space of the first-level PCIe fabric.

15. The PCIe topology of claim 12 , wherein the RCEP device comprises one or more root ports.

16. The PCIe topology of claim 12 , wherein the extended PCIe fabric comprises one or more switches electrically interconnecting one or more endpoints to the RCEP.

17. A method for designing peripheral devices comprising: including a root complex endpoint (RCEP) hosting an extended peripheral component interconnect express (PCIe) fabric as part of an endpoint of a host PCIe fabric, wherein the extended PCIe fabric comprises: a first MMIO space that is separate from a second MMIO space of the host PCIe fabric; and a first set of bus numbers that is separate from a second set of bus numbers of the host PCIe fabric, wherein the first set of bus numbers allows additional devices to be connected to a host computer processing unit (CPU) beyond a capacity of the host PCIe fabric as provided by resources a host root complex of the host PCIe fabric; mapping the second MMIO of the host PCIe fabric to a physical address on the host CPU, wherein the host PCIe fabric is a bridge between the extended PCIe fabric and the host CPU; and mapping the first MMIO space of the extended PCIe fabric to the second MMIO space of the host PCIe fabric.

18. The method of claim 17 , further comprising intercepting, by the RCEP device, downstream faults occurring on the extended PCIe fabric.

19. The method of claim 17 , further comprising mapping a PCIe configuration space, a 32-bit memory space, and a 64-bit memory space of the extended PCIe fabric to the second MMIO space.

20. The method of claim 17 , further comprising handling, by the RCEP device, device interrupts originating on the extended PCIe fabric using message signaled interrupts (MSIs).

21. The method of claim 17 , further comprising handling a direct memory access (DMA) request from a device connected to the extended PCIe fabric by replacing an originating device ID in a DMA request with a RCEP ID when the DMA request is forwarded upstream to the host PCIe fabric.